A Study on the Heat Transfer Performance Having Perforated Fins in Air Channel for Solar Air-water Heater using CFD

Journal of the Korean Solar Energy Society Pub Date : 2022-08-30 DOI:10.7836/kses.2022.42.4.033

Kwang-am Moon, In-han Lee, Hwi-Ung Choi, K. Choi

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Abstract

The solar air–water heater is a combined system of air-type and water-type collectors and a composite collector that can produce hot water and heated air in one system. Although it can maximize heat acquisition by transferring some of the heat lost from the absorbent plate and pipe toward the air duct, the heat acquisition is low due to the low heat capacity. To address this problem, several studies have been conducted using turbulent promoters in ducts. In this study, to improve the air-side heat transfer performance of the solar air–water heater, perforated fins on the bottom side of the absorption plate were arranged in various arrangements. Thereafter, computational fluid dynamics (CFD) was performed according to the flow conditions, and the heat transfer performance and pressure drop characteristics were analyzed. Results indicated that the heat transfer performance improved by at least 1.24 times to a maximum of 2.21 times, and that the pressure drop was in the range of 4.10 ~ 7.38 times, confirming the thermal hydraulic performance parameter (THPP). In the case of the performance coefficient, when perforated fins were attached side by side to the pipe, the highest performance coefficient was 1.18.

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太阳能空气热水器风道带孔翅片换热性能CFD研究

太阳能空气热水器是空气型集热器和水型集热器的组合系统，是一种能在一个系统中产生热水和被加热空气的复合集热器。虽然它可以通过将吸收板和管道损失的一些热量转移到风管来最大限度地获取热量，但由于热容量低，获取热量较低。为了解决这个问题，一些研究已经在管道中使用湍流启动子进行了。在本研究中，为了提高太阳能空气热水器的空气侧换热性能，在吸热板的底部以不同的排列方式布置了多孔翅片。然后，根据流动条件进行计算流体动力学(CFD)，分析传热性能和压降特性。结果表明:换热性能至少提高1.24倍，最大提高2.21倍，压降在4.10 ~ 7.38倍范围内，证实了热工性能参数(THPP)。在性能系数方面，当带孔翅片并排附着在管道上时，性能系数最高，为1.18。

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Journal of the Korean Solar Energy Society

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